KR100972655B1 - Assistance device for supporting GPR antenna - Google Patents

Abstract

The present invention relates to an auxiliary device for GPR exploration, and more particularly, it is possible to tow a heavy weight GPR (Ground Penetrating Radar) survey antenna for measuring the internal state of a concrete structure using electromagnetic waves in a stable and comfortable posture. By doing so, it relates to an auxiliary device for GPR exploration that can improve the exploration work convenience for concrete structures.

To this end, the present invention and the working plate of a predetermined area; A pair or two pairs of holder fixing plates arranged along the desired direction on the working plate; Clamping means for fixing both ends of the holder fixing plate; A support rod holder mounted on the holder fixing plate; An antenna support rod erected vertically while being inserted into the support rod holder; A rotation assembly for reversing rotationally mounted on an upper end of the antenna support rod in a vertical and horizontal direction; An antenna fixing rod having a predetermined length seated on the rotating assembly to enable vertical, left, and right directions switching; A GPR antenna fixed to an upper end of the antenna fixing rod; It provides an auxiliary device for GPR exploration, characterized in that configured to include.

GPR, exploration, auxiliary device, concrete structure, antenna, antenna fixing rod, work convenience

Description

Assistance device for supporting GPR antenna

The present invention relates to an auxiliary device for GPR exploration, and more particularly, it is possible to tow a heavy weight GPR (Ground Penetrating Radar) survey antenna for measuring the internal state of a concrete structure using electromagnetic waves in a stable and comfortable posture. By doing so, it relates to an auxiliary device for GPR exploration that can improve the exploration work convenience for concrete structures.

As is well known, after constructing a concrete structure such as a tunnel structure, a large building, etc., an exploration process is performed to determine the durability and the construction state of the rear surface after a predetermined time.

GPR (Ground Penetrating Radar) exploration method is mainly used among the methods of exploring the lifting or cavity of the back of the concrete structure using electromagnetic waves. The GPR antenna used for non-destructive inspection is 400 ~ 1000Mhz band Use electromagnetic waves.

Here, the conventional GPR exploration method will be described.

First, the operator directly holds the lower end of the antenna fixing rod of a predetermined length by standing it on the surface of the concrete structure, and then closes the GPR antenna fixed to the upper end of the antenna fixing rod to the concrete surface.

Subsequently, the GPR antenna is moved at a constant speed along the concrete surface while the worker walks or climbs on the trolley, and the movement distance and the moving speed of the GPR antenna affect the accuracy of the measurement. You must keep it.

At this time, while the electromagnetic wave of 400 ~ 1000Mhz band is transmitted and received through the transceiver of the GPR antenna moving along the concrete surface, the internal state of the concrete structure is displayed on the monitor of the measuring equipment connected to the GPR antenna so as to exchange signals.

However, the conventional GPR exploration method as described above has the following problems.

Although the weight of the GPR antenna varies depending on the depth of exploration and use, the weight of the concrete thickness survey antenna used for civil engineering structures is about 4.8 kg, so that the operator directly lifts the antenna fixing rod and simultaneously There is a great force to adhere to the concrete surface (especially the ceiling surface of the tunnel structure), and during continuous exploration, the operator hits the limit of force and cannot bear the weight of the GPR antenna, so that the GPR antenna is separated from the concrete surface There was a problem that exploration was not made.

In other words, the exploration of the bottom side of the concrete structure can be easily performed by the operator without affecting the weight of the GPR antenna, but when the ceiling surface and the shoulder surface of a large tunnel are explored, the GPR antenna and the antenna supporting it are fixed. Since the rod must be lifted directly, even if two or more workers are put together, there is a difficulty in continuous exploration due to the heavy weight.

In addition, the heavy weight of the GPR antenna should be moved in close contact with the concrete surface, but it must move like a skid, so it is difficult to maintain a constant gap between the GPR antenna and the concrete surface, so that stable and accurate exploration of the concrete structure is not made. There is a problem.

Also, since the GPR antenna is almost flat in contact with the concrete surface, if there is a bend on the concrete surface or an obstacle that obstructs the movement of the GPR antenna, the GPR antenna may interfere with the smooth movement of the GPR antenna. There is a difficulty in obtaining accurate measurement information.

The present invention has been made in view of the above, and when the GPR exploration work on a concrete structure, by mounting the GPR antenna and the antenna fixing rod supporting it firmly and freely to change the direction, the operator The purpose of the present invention is to provide an assisting device for GPR exploration, which enables accurate and convenient exploration of concrete structures while towing a ground penetrating radar antenna.

The present invention for achieving the above object is a working plate of a predetermined area; A pair or two pairs of holder fixing plates arranged along the desired direction on the working plate; Clamping means for fixing both ends of the holder fixing plate; A support rod holder mounted on the holder fixing plate; An antenna support rod erected vertically while being inserted into the support rod holder; A rotation assembly for reversing rotationally mounted on an upper end of the antenna support rod in a vertical and horizontal direction; An antenna fixing rod having a predetermined length seated on the rotating assembly to enable vertical, left, and right directions switching; A GPR antenna fixed to an upper end of the antenna fixing rod; It is to provide an auxiliary device for GPR exploration, characterized in that configured to include.

In a preferred embodiment, the holder fixing plate is a pair or two pairs are arranged on the working plate, each pair of holder fixing plate is a "b" shaped steel plate of a predetermined length having a plurality of slots formed along the longitudinal direction is arranged in two rows It features.

In another preferred embodiment, the clamping means comprises: a fixed neck which is in close contact with both ends of the holder fixing plate arranged on the working plate; An all-purpose machine for tightening the fixed wood and the work plate; Characterized in that consisting of.

As another preferred embodiment, the revolving assembly for rotation includes: a rotary rod rotatably inserted in the left and right directions on the upper end of the antenna support rod; A lower plate integrally assembled to the upper end of the rotating rod; A pair of side plates erected vertically at both sides of the lower plate; A roller rotatably mounted up and down on an inner surface of the side plate, on which the antenna fixing rod is seated; Characterized in that consisting of.

In another preferred embodiment, a pair of angle adjusting pieces having a plurality of angle adjusting holes are integrally formed on the bottom surface of the GPR antenna, and an assembly end inserted between the pair of angle adjusting pieces is provided on the top of the antenna fixing rod. It is formed integrally, characterized in that the assembly end is formed with a fastening hole matching the angle adjusting hole.

Through the above problem solving means, the present invention provides the following effects.

According to the present invention, during the GPR exploration work on the concrete structure, while fixing the support rod holder to the mounting plate fixed to the mounting plate fixed to the working plate, the antenna support rod vertically inserted into the support rod holder, the antenna support rod By mounting the antenna fixing rod with the GPR antenna fixed to the directional rotating assembly mounted on the top, the operator can tow the heavy weight GPR probe antenna in a stable and comfortable posture and adjust the direction while precisely exploring the concrete structure. It can be done conveniently.

Thus, the operator can directly grasp the antenna fixed rod equipped with a GPS antenna as in the prior art to perform the GPR exploration work to solve the inconvenience of the force more than the strength of the operator, it is possible to secure safe work for industrial safety.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing an auxiliary device for GPR exploration according to the present invention, Figure 2 is an auxiliary device for GPR exploration according to the present invention, the cradle fixing plate is arranged in the X-axis direction on the working plate, Fig. 3 is a plan view illustrating an example made, and Fig. 3 is a plan view illustrating an example in which a cradle fixing plate is arranged in the Y-axis direction on a working plate and a GPR exploration operation is performed as an auxiliary device for GPR exploration according to the present invention.

As shown in Figure 1, each of the components of the auxiliary device according to the present invention is installed on the upper plate of the moving trolley 56, that is, the working plate, first a pair or two on the working plate 10 in a desired direction Arrange the pair of holder fixing plate (12).

The cradle fixing plate 12 preferably uses a "b" shaped steel plate (a kind of angle type) of a predetermined length having a plurality of slots 26 formed along the length direction, and the "b" shaped steel sheet is a pair or two. They are arranged in pairs on the working plate 10 in pairs.

At this time, the holder fixing plate 12 arranged on the working plate 10 is fixed by the clamping means 14, as can be seen in the accompanying FIG. 5, the clamping means 14 to the working plate 10 It consists of a fixed wood 28 in close contact with both ends of the cradle fixed plate 12 arranged, and a plunger 30 to tighten the fixed wood 28 and the working plate 10 together.

Thus, both ends of the holder fixing plate 12 is in close contact with the fixed neck 28 tightened by the plunger 30, so that the holder fixing plate 12 on the working plate 10 maintains its arrangement position firmly. Done.

The mounting direction of the holder fixing plate 12 may be arranged in the X-axis direction as shown in FIG. 2 according to the exploration direction of the GPR antenna 24 with respect to the concrete structure (particularly, the ceiling surface of the tunnel). Or it may be arranged in the Y-axis direction.

In addition, as shown in FIG. 4 showing the unit for the holder fixing plate 12, the length of the holder fixing plate 12 can be adjusted according to the area of the working plate 10.

That is, after overlapping the two holder fixing plate 12 according to the area of the working plate 10, and tightening the bolt 52 and the nut 54 through the slot of the overlapping portion, the length of the holder fixing plate 12 I can regulate it.

On the other hand, the support rod holder 16 is seated and fixed to the holder fixing plate 12 fixed on the working plate 10 as described above, the exploration direction of the GPR antenna 24 to the concrete structure (particularly, the ceiling surface of the tunnel) Accordingly, it may be fixed and seated in a desired position as in the example shown in FIGS. 2 and 3.

In more detail, the support rod holder 16 is a rectangular plate-shaped mounting plate 48 seated on the mounting plate fixing plate 12 and fastened with a bolt or the like, and a coupler integrally formed at the center of the mounting plate 48. It consists of 50, and in fact, the mounting plate 48 is fixed to the desired position of the mounting plate fixing plate 12 to be fixed with a bolt and nut.

Therefore, when the antenna support rod 18 having a predetermined length is inserted into the coupling hole 50 of the support rod holder 16, the antenna support rod 18 is vertically erected.

Although only one antenna support rod 18 may be erected, it is preferable to apply one long and one short as shown in FIG. 1 for more stable operation.

Here, the rotation assembly 20 for switching the direction is mounted on the upper end of the antenna support rod 18 so as to rotate in the vertical direction.

In more detail, the direction turning assembly 20 is a rotary rod 32 that is rotatably inserted in the left and right directions on the upper end of the antenna support rod 18, and is integrally assembled to the upper end of the rotary rod 32 A lower plate 34 and a pair of side plates 36 which are vertically erected at both sides of the lower plate 34, and a rotary rod 32 inserted into the antenna support rod 18, and a lower plate 34. The side plate 36 is in a state capable of rotating in the left and right directions.

That is, when the rotating rod 32 inserted into the antenna support rod 18 is rotated left and right, the lower plate 34 and the side plate 36 which are integrally connected are also rotated left and right together.

In particular, the roller 38 is mounted on the inner surface of the side plate 36 to be rotated up and down, and the antenna fixing rod 22 is mounted on the surface of the roller 38 to be mounted.

As described above, the lower end of the antenna fixing rod 22 is a part that the operator grasps by hand, the upper end is equipped with a GPR antenna 24 in close contact with the surface of the concrete structure.

At this time, as a configuration for adjusting the angle between the GPR antenna 24 and the antenna fixing rod 22, a pair of angle adjusting piece 42 having a plurality of angle adjusting holes 40 on the bottom surface of the GPR antenna 24 ) Is integrally formed, and an assembly end 44 having a fastening hole 46 is integrally formed at an upper end of the antenna fixing rod 22.

Therefore, the assembly end 44 of the antenna fixing rod 22 is inserted between the angle adjusting pieces 42 of the GPR antenna 24, and then through the desired angle adjusting hole 40 and the fastening hole 46. By tightening the bolt and nut, the angle between the GPR antenna 24 and the antenna fixing rod 22 can be adjusted to a desired angle.

Here, a method for performing GPR exploration using the auxiliary device of the present invention having the above configuration will be described.

First, the operator grasps the antenna fixing rod 22 and mounts it on the roller 38 of the rotation assembly 20 for redirection, and simultaneously mounts the GPR antenna 24 on the concrete structure (especially, the ceiling surface of the tunnel). To the surface of the

At this time, since the GPR antenna 24 and the antenna fixing rod 22 are already fixed to the roller 38 of the rotation assembly 20 for turning direction, the operator is in close contact with the surface of the concrete structure GPR antenna 24 It is only necessary to hold the lower end of the antenna fixing rod 22 with very little force so that it does not fall.

Subsequently, when the moving cart 56 moves, the GPR antenna 24 in close contact with the surface of the concrete structure moves along the concrete structure, and thus GPR exploration of the concrete structure is performed.

In order to explore another part of the concrete structure or another concrete structure, the arrangement direction of the mounting plate 12 is determined according to the direction of exploration of the GPR antenna 24 with respect to the concrete structure (particularly, the ceiling surface of the tunnel). Alternatively, the rearrangement in the Y-axis direction may be performed by remounting the support rod holder 16 to the desired position on the mount holder plate 12 to vary the position of the antenna support rod 18.

In addition, when the antenna fixing rod 22 is rotated in the desired direction by the operator, the left and right rotation operation of the rotating rod 32 inserted into the antenna support rod 18 and the roller 38 on which the antenna fixing rod 22 is seated. According to the vertical rotation operation of the), the antenna fixing rod 22 may be moved in a desired direction, and eventually the GPR antenna 24 fixed to the upper end of the antenna fixing rod 22 may be moved to a desired position.

In addition, when an obstacle (a wiring device installed on the ceiling surface of the tunnel) appears during the exploration of the concrete structure, the antenna fixing rod 22 may be slightly lowered while being assisted by the rolling operation of the roller 38. After passing through the obstacle, the roller 38 may be lifted again while receiving the rolling motion of the roller 38.

Thus, with respect to the desired surface of the concrete structure, accurate exploration can be made while moving the GPR antenna 24, and in particular, the operator can tow the heavy-weight GPR probe antenna in a stable and comfortable posture while controlling the orientation to the concrete structure. The exploration work can be performed accurately and conveniently.

1 is a perspective view showing an auxiliary device for GPR exploration according to the present invention,

2 is an auxiliary device for GPR exploration according to the present invention, a cradle fixing plate is arranged in the X-axis direction on the working plate, a plan view illustrating an example in which a GPR exploration operation is performed;

3 is an auxiliary device for GPR exploration according to the present invention, a cradle fixing plate is arranged in the Y-axis direction on the working plate, a plan view illustrating an example in which a GPR exploration operation is performed;

Figure 4 is a perspective view showing the state of the holder fixing plate of the configuration of the auxiliary device for GPR exploration according to the present invention,

Figure 5 is a perspective view showing the clamping means of the configuration of the auxiliary device for GPR exploration according to the present invention,

Figure 6 is a perspective view showing a rotating assembly for the direction of configuration of the auxiliary device for GPR exploration according to the present invention,

7 is a perspective view showing a connection structure between a GPR antenna and an antenna fixing rod of the auxiliary device for the GPR exploration according to the present invention;

Figure 8 is a schematic diagram illustrating the exploration work on the concrete structure (tunnel) using the auxiliary device for GPR exploration according to the present invention.

<Explanation of symbols for the main parts of the drawings>

10: working plate 12: holder fixing plate

14 clamping means 16 support rod holder

18: antenna support rod 20: rotation assembly for turning direction

22: antenna fixing rod 24: GPR antenna

26: slot 28: fixed wood

30: pneumatic 32: rotating rod

34: lower plate 36: side plate

38: roller 40: angle adjustment hole

42: angle adjusting piece 44: assembly stage

46: fastening hole 48: mounting plate

50: coupler 52: bolt

54: nut 56: moving cart

Claims (5)

A working plate 10 having a predetermined area; A pair or two pairs of holder fixing plates 12 arranged along the desired direction on the working plate 10; Clamping means (14) for fixing both ends of the holder fixing plate (12) without moving; A support rod holder 16 mounted on the holder fixing plate 12; An antenna support rod 18 vertically inserted into the support rod holder 16; A rotation assembly (20) for turning the upper and lower sides of the antenna support bar (18) rotatably mounted; An antenna fixing rod (22) of a predetermined length seated on the rotating assembly (20) so as to be capable of changing up, down, left and right directions; A GPR antenna 24 fixed to an upper end of the antenna fixing rod 22; An auxiliary device for GPR exploration, characterized in that configured to include. According to claim 1, wherein the holder fixing plate 12 is a pair or two pairs are arranged on the work plate 10, each pair of holder fixing plate 12 is a predetermined number of slots 26 are formed along the longitudinal direction An auxiliary device for GPR exploration characterized in that the "b" shaped steel sheets of length are arranged in two rows. The clamping means (14) of claim 1 wherein: A fixed wood 28 in close contact with both ends of the holder fixing plate 12 arranged on the working plate 10; Plunger 30 for tightening the fixed wood 28 and the working plate 10 together; An auxiliary device for GPR exploration, characterized in that consisting of. The method of claim 1, wherein the rotating assembly 20 for turning: Rotating rod 32 is rotatably inserted in the left and right directions on the top of the antenna support rod (18); A lower plate 34 integrally assembled to an upper end of the rotating rod 32; A pair of side plates 36 which are vertically erected at both sides of the lower plate 34; A roller 38 mounted on an inner surface of the side plate 36 to be rotatable vertically, in which the antenna fixing rod 22 is seated; An auxiliary device for GPR exploration, characterized in that consisting of. 2. The pair of angle adjusting pieces 42 having a plurality of angle adjusting holes 40 are integrally formed on a bottom surface of the GPR antenna 24, and an upper end of the antenna fixing rod 22 is formed on the bottom surface of the GPR antenna 24. Assembly stage 44 is inserted into the pair between the angle adjusting piece 42 is formed integrally, the assembly end 44 is characterized in that the fastening hole 46 matching the angle adjusting hole 40 is formed Auxiliary device for GPR exploration.

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